Assessment of the role of alpha2-adrenoceptor subtypes in the antinociceptive, sedative and hypothermic action of dexmedetomidine in transgenic mice.

1. The role of alpha2-adrenoceptor (AR) subtypes in the modulation of acute nociception, motor behaviour and body temperature, has been investigated by determining the activity of the alpha2AR selective agonist dexmedetomidine (Dex) in mice devoid of individual alpha2AR subtypes through either a point (alpha2A) or null (alpha2B/alpha2C) mutation ('knock-out'). 2. In a rodent model of acute thermal nociception, the mouse tail immersion test, Dex, in wild type (WT) control animals, produced a dose-dependent increase in the threshold for tail withdrawal from a 52 degrees C water bath with mean ED50 values of 99.9+/-14.5 (alpha2A), 94.6+/-17.8 (alpha2B) and 116.0/-17.1 (alpha2C) microg kg(-1), i.p. 3. In comparison to the WT controls, Dex (100-1000 microg kg(-1), i.p.), was completely ineffective as an antinociceptive agent in the tail immersion test in the alpha2A AR D79N mutant animals. Conversely, in the alpha2B AR and alpha2C AR knock-outs, Dex produced a dose-dependent antinociceptive effect that was not significantly different from that observed in WT controls, with ED50 values of 85.9+/-15.0 (P>0.05 vs WT control) and 226.0+/-62.7 (P>0.05 vs WT control) microg kg(-1) i.p., respectively. 4. Dex (10-300 microg kg(-1), i.p.) produced a dose-dependent reduction in spontaneous locomotor activity in the alpha2A, alpha2B and alpha2C AR WT control animals with ED50 values of 30.1+/-9.0, 23.5+/-7.1 and 32.3+/-4.6 microg kg(-1), i.p., respectively. Again, Dex (100-1000 microg kg(-1), i.p.) was ineffective at modulating motor behaviour in the alpha2A AR D79N mutants. In the alpha2B AR and alpha2C AR knock-out mice, Dex produced a dose-dependent reduction in spontaneous locomotor activity with ED50 values of 29.1+/-6.4 (P>0.05 vs WT control) and 57.5+/-11.3 (P>0.05 vs WT control) microg kg(-1), respectively. 5. Dex was also found to produce a dose-dependent reduction in body temperature in the alpha2A, alpha2B and alpha2C AR WT control mice with ED50 values of 60.6+/-11.0, 16.2+/-2.5 and 47.2+/-9.1 microg kg(-1), i.p., respectively. In the alpha2A AR D79N mutants, Dex had no effect on body temperature at a dose (100 microg kg(-1), i.p.) that produced a significant reduction (-6.2+/-0.5 degrees C; P<0.01 vs vehicle) in temperature in WT controls. However, higher doses of Dex (300 and 1000 microg kg(-1), i.p) produced a small, but statistically significant decrease in temperature corresponding to -1.7+/-0.4 degrees C and -2.4+/-0.3 degrees C (both P<0.01 vs vehicle), respectively. In the alpha2B AR and alpha2C AR knock-out mice, Dex produced a dose-dependent reduction in body temperature with ED50 values of 28.4+/-4.8 (P>0.05 vs WT control) and 54.1+/-8.0 (P>0.05 vs WT control) microg kg(-1), respectively. 6. In conclusion, the data are consistent with the alpha2A AR being the predominant subtype involved in the mediation of the antinociceptive, sedative and hypothermic actions of Dex. This profile would appear to indicate that an alpha2A AR subtype selective analgesic will have a narrow therapeutic window, particularly following systemic administration.